Rabies, Still Neglected after 125 Years of Vaccination

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Phylogenetic relationships among rhabdoviruses inferred using the L polymerase gene

RNA viruses of the family Rhabdoviridae include arthropod-borne agents that infect plants, fish and mammals, and also include a variety of non-vector-borne mammalian viruses. Herein is presented a molecular phylogenetic analysis, the largest undertaken to date, of 56 rhabdoviruses, including 20 viruses which are currently unassigned or assigned as tentative species within the Rhabdoviridae. Degenerate primers targeting a region of block III of the L polymerase gene were defined and used for RT-PCR amplification and sequencing. A maximum-likelihood phylogenetic analysis of a 158-residue L polymerase amino acid sequence produced an evolutionary tree containing the six recognized genera of the Rhabdoviridae and also enabled us to identify four more monophyletic groups of currently unclassified rhabdoviruses that we refer to as the 'Hart Park', 'Almpiwar', 'Le Dantec' and 'Tibrogargan' groups. The broad phylogenetic relationships among these groups and genera also indicate that the evolutionary history of rhabdoviruses was strongly influenced by mode of transmission, host species (plant, fish or mammal) and vector (orthopteran, homopteran or dipteran)

The matrix protein of rabies virus binds to RelAp43 to modulate NF-κB-dependent gene expression related to innate immunity.

The matrix (M) protein of wild isolates of rabies virus such as Tha (M-Tha) was previously shown to be able to interact with RelAp43, a protein of the NF-κB family, and to efficiently suppress NF-κB-dependent reporter gene expression, in contrast with the vaccine strain SAD. Here, we analyze the mechanisms involved in RelAp43-M protein interaction. We demonstrate that the central part of M-Tha, and the specific C-terminal region of RelAp43 are required for this interaction. Four differences in the corresponding amino acid sequences of the M-Tha and M-SAD are shown to be crucial for RelAp43 interaction and subsequent modulation of innate immune response. Furthermore, the capacity of M-Tha to interact with RelAp43 was shown to be crucial for the control of the expression of four genes (IFN, TNF, IL8 and CXCL2) during viral infection. These findings reveal that RelAp43 is a potent regulator of transcription of genes involved in innate immune response during rabies virus infection and that the M protein of wild isolates of rabies virus is a viral immune-modulatory factor playing an important role in this RelAp43-mediated host innate immunity response in contrast to M protein of vaccine strains, which have lost this property

Interaction of Rabies Virus P-Protein With STAT Proteins is Critical to Lethal Rabies Disease

BACKGROUND: Rabies virus (RABV) causes rabies disease resulting in >55,000 human deaths/year. The multifunctional RABV P-protein has essential roles in genome replication, and forms interactions with cellular STAT proteins that are thought to underlie viral antagonism of interferon-dependent immunity. However, the molecular details of P-protein-STAT interaction, and its importance to disease are unresolved. METHODS: Studies were performed using sequence/structure analysis, mutagenesis, immunoprecipitation, luciferase and qRT-PCR-based signaling assays, confocal microscopy and reverse genetics/in vivo infection. RESULTS: We identified a hydrophobic pocket of the P-protein C-terminal domain as critical to STAT-binding/antagonism. This interface was found to be functionally and spatially independent of the region responsible for N-protein interaction, which is critical to genome replication. Based on these findings, we generated the first mutant RABV lacking STAT-association. Growth of the virus in vitro was unimpaired, but it lacked STAT-antagonist function and was highly sensitive to interferon. Importantly, growth of the virus was strongly attenuated in brains of infected mice, producing no major neurological symptoms, compared with the invariably lethal wild-type virus. CONCLUSIONS: These data represent direct evidence that P-protein-STAT interaction is critical to rabies, and provide novel insights into the mechanism by which RABV coordinates distinct functions in interferon antagonism and replication

Conservation of a unique mechanism of immune evasion across the Lyssavirus genus.

International audienceThe evasion of host innate immunity by Rabies virus, the prototype of the genus Lyssavirus, depends on a unique mechanism of selective targeting of interferon-activated STAT proteins by the viral phosphoprotein (P-protein). However, the immune evasion strategies of other lyssaviruses, including several lethal human pathogens, are unresolved. Here, we show that this mechanism is conserved between the most distantly related members of the genus, providing important insights into the pathogenesis and potential therapeutic targeting of lyssaviruses